The UBL domain of PLIC-1 regulates aggresome formation

Defects in protein folding and the proteasomal pathway have been linked with many neurodegenerative diseases. PLIC-1 (protein linking IAP to the cytoskeleton) is a ubiquitin-like protein that binds to the ubiquitin-interacting motif (UIM) of the proteasomal subunit S5a. Here, we show that PLIC-1 also binds to the UIM proteins ataxin 3--a deubiquitinating enzyme--HSJ1a--a co-chaperone--and EPS15 (epidermal growth factor substrate 15)--an endocytic protein. Using a polyglutamine (polyQ) disease model, we found that both endogenous PLIC-1 and EPS15 localize to perinuclear aggresomes, and that polyQ enhances their in vivo interaction. We show that knockdown of PLIC-1 and EPS15 by RNA interference reduces aggresome formation. In addition, PLIC-1(DeltaUBL) functions as a dominant-negative mutant, blocking both polyQ transport to aggresomes and the association of EPS15 with dispersed aggregates. We also show that PLIC-1 is upregulated by arsenite-induced protein misfolding. These results indicate a role for PLIC-1 in the protein aggregation-stress pathway, and we propose a novel function for the ubiquitin-like (UBL) domain--by means of UBL-UIM interactions--in transport to aggresomes.     

Ubiquitin-related proteins regulate interaction of vimentin intermediate filaments with the plasma membrane.

Integrin-associated protein (IAP, CD47) is a plasma membrane receptor for thrombospondins and signal regulatory proteins (SIRPs) that has an essential role in host defense through its association with integrins. The IAP gene encodes alternatively spliced carboxyterminal cytoplasmic tails that have no previously described function. IAP cytoplasmic tails can bind two related proteins that mediate interaction between IAP and vimentin-containing intermediate filaments, named proteins linking IAP with cytoskeleton (PLICs). Integrins interact with PLICs indirectly, through IAP. Transfection of PLICs induces redistribution of vimentin and cell spreading in IAP-expressing cells. This novel connection between plasma membrane and cytoskeleton is likely to be significant in many adhesion-dependent cell functions.     

Proteasome regulates the delivery of LDL receptor-related protein into the degradation pathway

The low-density lipoprotein receptor (LDLR)-related protein (LRP) is a multiligand endocytic receptor that has broad cellular and physiological functions. Previous studies have shown that both tyrosine-based and di-leucine motifs within the LRP cytoplasmic tail are responsible for mediating its rapid endocytosis. Little is known, however, about the mechanism by which LRP is targeted for degradation. By examining both endogenous full-length and a minireceptor form of LRP, we found that proteasomal inhibitors, MG132 and lactacystin, prolong the cellular half-life of LRP. The presence of proteasomal inhibitors also significantly increased the level of LRP at the cell surface, suggesting that the delivery of LRP to the degradation pathway was blocked at a compartment from which recycling of the receptor to the cell surface still occurred. Immunoelectron microscopy analyses demonstrated a proteasomal inhibitor-dependent reduction in LRP minireceptor within both limiting membrane and internal vesicles of the multivesicular bodies, which are compartments that lead to receptor degradation. In contrast to the growth hormone receptor, we found that the initial endocytosis of LRP minireceptor does not require a functional ubiquitin-proteasome system. Finally, using truncated cytoplasmic mutants of LRP minireceptors, we found that a region of 19 amino acids within the LRP tail is required for proteasomal regulation. Taken together our results provide strong evidence that the cellular turnover of a cargo receptor, i.e., LRP, is regulated by the proteasomal system, suggesting a broader function of the proteasome in regulating the trafficking of receptors into the degradation pathway.     

Degradation of misfolded protein in the cytoplasm is mediated by the ubiquitin ligase Ubr1

Protein quality control and subsequent elimination of terminally misfolded proteins occurs via the ubiquitin-proteasome system. Tagging of misfolded proteins with ubiquitin for degradation depends on a cascade of reactions involving an ubiquitin activating enzyme (E1), ubiquitin conjugating enzymes (E2) and ubiquitin ligases (E3). While ubiquitin ligases responsible for targeting misfolded secretory proteins to proteasomal degradation (ERAD) have been uncovered, no such E3 enzymes have been found for elimination of misfolded cytoplasmic proteins in yeast. Here we report on the discovery of Ubr1, the E3 ligase of the N-end rule pathway, to be responsible for targeting misfolded cytosoplasmic protein to proteasomal degradation.     

The ubiquitin-like protein PLIC-2 is a negative regulator of G protein-coupled receptor endocytosis

The activity of many signaling receptors is regulated by their endocytosis via clathrin-coated pits (CCPs). For G protein-coupled receptors (GPCRs), recruitment of the adaptor protein arrestin to activated receptors is thought to be sufficient to drive GPCR clustering in CCPs and subsequent endocytosis. We have identified an unprecedented role for the ubiquitin-like protein PLIC-2 as a negative regulator of GPCR endocytosis. Protein Linking IAP to Cytoskeleton (PLIC)-2 overexpression delayed ligand-induced endocytosis of two GPCRs: the V2 vasopressin receptor and β-2 adrenergic receptor, without affecting endocytosis of the transferrin or epidermal growth factor receptor. The closely related isoform PLIC-1 did not affect receptor endocytosis. PLIC-2 specifically inhibited GPCR concentration in CCPs, without affecting membrane recruitment of arrestin-3 to activated receptors or its cellular levels. Depletion of cellular PLIC-2 accelerated GPCR endocytosis, confirming its regulatory function at endogenous levels. The ubiquitin-like domain of PLIC-2, a ligand for ubiquitin-interacting motifs (UIMs), was required for endocytic inhibition. Interestingly, the UIM-containing endocytic adaptors epidermal growth factor receptor protein substrate 15 and Epsin exhibited preferential binding to PLIC-2 over PLIC-1. This differential interaction may underlie PLIC-2 specific effect on GPCR endocytosis. Identification of a negative regulator of GPCR clustering reveals a new function of ubiquitin-like proteins and highlights a cellular requirement for exquisite regulation of receptor dynamics.     

Kaposi's sarcoma-associated herpesvirus K7 protein targets a ubiquitin-like/ubiquitin-associated domain-containing protein to promote protein degradation

Pathogens exploit host machinery to establish an environment that favors their propagation. Because of their pivotal roles in cellular physiology, protein degradation pathways are common targets for viral proteins. Protein-linking integrin-associated protein and cytoskeleton 1 (PLIC1), also called ubiquilin, contains an amino-terminal ubiquitin-like (UBL) domain and a carboxy-terminal ubiquitin-associated (UBA) domain. PLIC1 is proposed to function as a regulator of the ubiquitination complex and proteasome machinery. Kaposi's sarcoma-associated herpesvirus (KSHV) contains a small membrane protein, K7, that protects cells from apoptosis induced by various stimuli. We report here that cellular PLIC1 is a K7-interacting protein and that the central hydrophobic region of K7 and the carboxy-terminal UBA domain of PLIC1 are responsible for their interaction. Cellular PLIC1 formed a dimer and bound efficiently to polyubiquitinated proteins through its carboxy-terminal UBA domain, and this activity correlated with its ability to stabilize cellular I kappa B protein. In contrast, K7 interaction prevented PLIC1 from forming a dimer and binding to polyubiquitinated proteins, leading to the rapid degradation of I kappa B. Furthermore, K7 expression promoted efficient degradation of the p53 tumor suppressor, resulting in inhibition of p53-mediated apoptosis. These results indicate that KSHV K7 targets a regulator of the ubiquitin- and proteasome-mediated degradation machinery to deregulate cellular protein turnover, which potentially provides a favorable environment for viral reproduction.     

3D single-particle tracking and optical trap measurements on adhesion proteins.

A three-dimensional single-particle tracking system was combined with an optical trap to investigate the behavior of transmembrane adhesion proteins. We exploited this setup to investigate which part of the cell adhesion protein LFA-1 forms a connection to the cytoskeleton after binding to its ligand ICAM-1. LFA-1 is an integrin consisting of an alpha and a beta chain. Thus far, only the cytoplasmic tail of the beta chain is known to form a connection to the cytoskeleton. We investigated cells that express a mutant form of LFA-1 that lacks the complete beta cytoplasmic tail and therefore is not thought to bind to the cytoskeleton. Interestingly, single-particle tracking measurements using beads coated with the ligand ICAM-1 indicate that this mutant form of LFA-1 does not move freely within the cell membrane, suggesting that LFA-1 is still connected to the cytoskeleton network. This finding is strongly supported by the observation that LFA-1 exhibits a more diffusive motion when the cytoskeleton network is disrupted and confirmed by the optical trap measurements used to force the proteins to move through the membrane. Collectively, our findings suggest that the interaction of LFA-1 with the cytoskeleton cannot solely be attributed to the cytoplasmic part of the beta chain.     

Human immunodeficiency virus type 1 Vpu protein induces degradation of chimeric envelope glycoproteins bearing the cytoplasmic and anchor domains of CD4: role of the cytoplasmic domain in Vpu-induced degradation in the endoplasmic reticulum.

The human immunodeficiency virus type 1 (HIV-1) Vpu protein is a transmembrane phosphoprotein which induces rapid degradation of CD4 in the endoplasmic reticulum (ER). To identify sequences in CD4 for Vpu-induced degradation, we generated four chimeric envelope glycoproteins having the ectodomain of HIV-1 gp160, the anchor domain of CD4, and 38, 25, 24, and 18 amino acids (aa) of the CD4 cytoplasmic domain. Using the vaccinia virus-T7 RNA polymerase expression system, we analyzed the expression of chimeric proteins in the presence and absence of Vpu. In singly transfected cells, the chimeric envelope glycoproteins having 38, 24, and 18 aa of the CD4 cytoplasmic domain were endoproteolytically cleaved and biologically active in the fusion of HeLa CD4+ cells. However, one of the chimeras having 25 aa of the CD4 cytoplasmic tail was retained in the ER using the transmembrane ER retention signal and was defective in membrane fusion. Furthermore, biochemical analyses of the coexpressing cells revealed that the Vpu protein induced degradation of the envelope glycoproteins having 38, 25, and 24 aa of the CD4 cytoplasmic tail and degradation occurred in the ER. Consequently, the fusion-competent glycoproteins did not induce the formation of syncytia in HeLa CD4+ cells expressing Vpu. However, the HIV-1 gp160 and chimeric envelope glycoprotein having the membrane-proximal 18 aa of the CD4 cytoplasmic tail were stable and fusion competent in cells expressing Vpu. In addition, we examined the stability of CD4 molecules in the presence of Vpu. Coexpression analyses revealed that the Vpu protein induced degradation of CD4 whereas mutant CD4 having the membrane-proximal 18 aa of the cytoplasmic domain was relatively stable in the presence of Vpu. Taken together, these studies have elucidated that the Vpu protein requires sequences or sequence determinants in the cytoplasmic domain of CD4 to induce degradation of the glycoproteins in the cell.     

Structural requirements for CD43 function

The regulation of T cell activation and adhesion by CD43 (leukosialin, sialophorin) has been thought to be mainly a function of the large size and negative charge of the extracellular domain of the protein. In this work, we demonstrate that the cytoplasmic tail is both necessary and sufficient for the negative regulatory effect of CD43 on cell-cell adhesion. Expression of mutant CD43 proteins in primary T cells from CD43-deficient mice demonstrated that the antiproliferative effect of CD43 is also dependent upon the cytoplasmic tail. In contrast, Ab-mediated costimulation through CD43 does not require the intracellular domain of CD43. These data demonstrate that CD43 primarily serves as a negative regulator of T cell activation and adhesion, and that this is mediated not exclusively by passive effects of the extracellular domain, but requires participation of the cytoplasmic tail, perhaps through interactions with the cytoskeleton, or alternatively, active regulation of intracellular signaling pathways.     

BAP31 interacts with Sec61 translocons and promotes retrotranslocation of CFTRDeltaF508 via the derlin-1 complex

BAP31 is an endoplasmic reticulum protein-sorting factor that associates with newly synthesized integral membrane proteins and controls their fate (i.e., egress, retention, survival, or degradation). BAP31 is itself an integral membrane protein and a constituent of several large protein complexes. Here, we show that a part of the BAP31 population interacts with two components of the Sec61 preprotein translocon, Sec61beta and TRAM. BAP31 associates with the N terminus of one of its newly synthesized client proteins, the DeltaF508 mutant of CFTR, and promotes its retrotranslocation from the ER and degradation by the cytoplasmic 26S proteasome system. Depletion of BAP31 reduces the proteasomal degradation of DeltaF508 and permits a significant fraction of the surviving protein to reach the cell surface. Of note, BAP31 also associates physically and functionally with the Derlin-1 protein disclocation complex in the DeltaF508 degradation pathway. Thus, BAP31 operates at early steps to deliver newly synthesized CFTRDeltaF508 to its degradation pathway.     

The ubiquitin-related protein PLIC-1 regulates heterotrimeric G protein function through association with Gbetagamma

PLIC-1, a newly described ubiquitin-related protein, inhibited both Jurkat migration toward SDF-1alpha and A431 wound healing, but the closely related PLIC-2 did not. PLIC-1 prevented the SDF-1alpha-induced activation of phospholipase C, decreased ligand-induced internalization of SDF-1alpha receptor CXCR4 and inhibited chemotaxis signaled by a transfected Gi-coupled receptor. However, PLIC-1 had no effect on Gs-mediated adenylyl cyclase activation, and inhibited only the Gbetagamma-dependent component of Gq-initiated increase in [Ca2+]i, which is consistent with selective inhibition of Gbetagamma function. PLIC-1 colocalized with G proteins in lamellae and pseudopods, and precipitated Gbetagamma in pull downs. Interaction with Gbetagamma did not require PLIC-1's ubiquitin-like or ubiquitin-associated domains, and proteasome inhibition had no effect on SDF-1alpha activation of phospholipase C, indicating that PLIC-1's inhibition of Gbetagamma did not result from effects on proteasome function. Thus, PLIC-1 inhibits Gi signaling by direct association with Gbetagamma; because it also interacts with CD47, a modulator of integrin function, it likely has a role integrating adhesion and signaling components of cell migration.     

Vpu-mediated degradation of CD4 reconstituted in yeast reveals mechanistic differences to cellular ER-associated protein degradation

In HIV infected cells, the plasma membrane protein CD4 is removed from the secretory pathway by proteasomal digestion. This crucial step of viral infection occurs at the endoplasmic reticulum and is triggered by the HIV encoded protein Vpu. Here we show that this process can be recapitulated in baker's yeast. The analysis in the yeast system revealed that Vpu-induced breakdown of CD4 occurs independently of the cellular ER-associated protein degradation system. Moreover, our system allows direct comparison between Vpu-mediated turnover and cellular ER-associated protein degradation of CD4. This analysis suggests fundamental mechanistic differences between both pathways: Vpu-induced turnover strictly relies on ubiquitination of CD4 at cytosolic lysine residues prior to export of the substrate from the membrane. In contrast, the cellular ER-associated protein degradation pathway can transport ER-lumenal parts of CD4 into the cytoplasm before ubiquitination and extraction of the membrane anchor.     

Targeting of lysosomal integral membrane protein LIMP II. The tyrosine-lacking carboxyl cytoplasmic tail of LIMP II is sufficient for direct targeting to lysosomes.

Time course experiments of the localization of rat LIMP II expressed in COS cells show that the protein is transported directly from the Golgi complex to lysosomes. Substitution of the tyrosine-lacking carboxyl cytoplasmic tail of LIMP II for the native cytoplasmic tails of the plasma membrane proteins CD36 and CD8 resulted in straight transport of both proteins to lysosomes. The synthetic tyrosine-containing heptapeptide, RGTGVYG, did not replace the natural carboxyl cytoplasmic tail of LIMP II in its ability to transport both CD36 and CD8 to lysosomes, and the two constructs were transported to and expressed at the plasma membrane. Substitution of the cytoplasmic tails of either CD36 or CD8 for the carboxyl cytoplasmic tail of LIMP II resulted in transport of the mutants to the plasma membrane where they underwent endocytosis before accumulating into lysosomes. The results indicate that a motif contained in the tyrosine-lacking carboxyl cytoplasmic tail of LIMP II is sufficient to target proteins directly from the Golgi complex to lysosomes.     

The Cytoplasmic Tail of Rhodopsin Acts as a Novel Apical Sorting Signal in Polarized MDCK Cells

All basolateral sorting signals described to date reside in the cytoplasmic domain of proteins, whereas apical targeting motifs have been found to be lumenal. In this report, we demonstrate that wild-type rhodopsin is targeted to the apical plasma membrane via the TGN upon expression in polarized epithelial MDCK cells. Truncated rhodopsin with a deletion of 32 COOH-terminal residues shows a nonpolar steady-state distribution. Addition of the COOH-terminal 39 residues of rhodopsin redirects the basolateral membrane protein CD7 to the apical membrane. Fusion of rhodopsin''s cytoplasmic tail to a cytosolic protein glutathione S-transferase (GST) also targets this fusion protein (GST–Rho39Tr) to the apical membrane. The targeting of GST–Rho39Tr requires both the terminal 39 amino acids and the palmitoylation membrane anchor signal provided by the rhodopsin sequence. The apical transport of GST–Rho39Tr can be reversibly blocked at the Golgi complex by low temperature and can be altered by brefeldin A treatment. This indicates that the membrane-associated GST–Rho39Tr protein may be sorted along a yet unidentified pathway that is similar to the secretory pathway in polarized MDCK cells. We conclude that the COOH-terminal tail of rhodopsin contains a novel cytoplasmic apical sorting determinant. This finding further indicates that cytoplasmic sorting machinery may exist in MDCK cells for some apically targeted proteins, analogous to that described for basolaterally targeted proteins.     

The cytoplasmic tail of CD44 is required for basolateral localization in epithelial MDCK cells but does not mediate association with the detergent-insoluble cytoskeleton of fibroblasts

A number of recent reports on the trafficking of receptor proteins in MDCK epithelial cells have provided evidence that delivery to the basolateral domain requires a specific targeting sequence and that deletion of this sequence results in constitutive expression on the apical surface. To date, these studies have concentrated on receptors which are competent for internalization via the clathrin coated pits. We have examined the localization of a resident plasma membrane protein by transfecting human CD44 into MDCK cells. Using human specific and cross-species reactive antibodies, we show that in MDCK cells both the endogenous and transfected wild-type CD44 are found on the basolateral surface where they are restricted to the lateral domain. Deletion of the CD44 cytoplasmic tail reduces the half life of this mutant protein and causes it to be expressed both on the apical surface and to a significant extent within the cell. We have also used biochemical and morphological analysis to investigate the interaction of CD44 with the cytoskeleton in detergent extracted cells. Strikingly different extraction results were obtained between epithelial and fibroblast cells. However, there is no difference in the Triton X-100 solubility of the transfected wild-type and tail-less CD44 in fibroblasts and both forms of the protein remain associated with the cortical cytoskeleton after Triton X-100 extraction. These results demonstrate that the sequence present in the cytoplasmic domain of CD44 responsible for its distribution in epithelial cells is functionally and spatially separate from the ability of this protein to associate with the cytoskeleton.     

Vpu Downmodulates Two Distinct Targets,Tetherin and Gibbon Ape Leukemia Virus Envelope,through Shared Features in the Vpu Cytoplasmic Tail

During human immunodeficiency virus-1 (HIV-1) assembly, the host proteins CD4 (the HIV-1 receptor) and tetherin (an interferon stimulated anti-viral protein) both reduce viral fitness. The HIV-1 accessory gene Vpu counteracts both of these proteins, but it is thought to do so through two distinct mechanisms. Modulation of CD4 likely occurs through proteasomal degradation from the endoplasmic reticulum. The exact mechanism of tetherin modulation is less clear, with possible roles for degradation and alteration of protein transport to the plasma membrane. Most investigations of Vpu function have used different assays for CD4 and tetherin. In addition, many of these investigations used exogenously expressed Vpu, which could result in variable expression levels. Thus, few studies have investigated these two Vpu functions in parallel assays, making direct comparisons difficult. Here, we present results from a rapid assay used to simultaneously investigate Vpu-targeting of both tetherin and a viral glycoprotein, gibbon ape leukemia virus envelope (GaLV Env). We previously reported that Vpu modulates GaLV Env and prevents its incorporation into HIV-1 particles through a recognition motif similar to that found in CD4. Using this assay, we performed a comprehensive mutagenic scan of Vpu in its native proviral context to identify features required for both types of activity. We observed considerable overlap in the Vpu sequences required to modulate tetherin and GaLV Env. We found that features in the cytoplasmic tail of Vpu, specifically within the cytoplasmic tail hinge region, were required for modulation of both tetherin and GaLV Env. Interestingly, these same regions features have been determined to be critical for CD4 downmodulation. We also observed a role for the transmembrane domain in the restriction of tetherin, as previously reported, but not of GaLV Env. We propose that Vpu may target both proteins in a mechanistically similar manner, albeit in different cellular locations.     

Dual regulation of SIRPalpha phosphorylation by integrins and CD47

Signal regulatory protein alpha (SIRPalpha, SHPS-1) is a plasma membrane receptor for CD47 and a key regulator of phagocytosis, growth factor signaling, and migration. Phosphorylation of immunoreceptor tyrosine-based inhibition motifs in its cytoplasmic tail is essential for the functional effects of SIRPalpha, at least in part, because the phosphorylated immunoreceptor tyrosine-based inhibition motifs recruit Src homology 2 domain-containing tyrosine phosphatases. Ligation by CD47 and integrin engagement both have been thought to regulate SIRPalpha phosphorylation. However, their distinct contributions have not been distinguished. Here, we show that the importance of CD47 varies with cell type, since ligation of CD47 is not necessary for SIRPalpha phosphorylation in myeloid cells, whereas it is required in endothelial cells. In contrast, integrin-mediated adhesion is required for SIRPalpha phosphorylation in both cell types. This shows that SIRPalpha phosphorylation is dually regulated and demonstrates a new mechanism for functional cooperation between integrins and the integrin-associated protein CD47.